Post on 24-Dec-2015
Transformer
Laboratorium Penelitian Konversi Energi ElektrikInstitut Teknologi Bandung
Agus Purwadi, Qamaruzzaman & Nana Heryana
Transformer
A A transformertransformer is a device that is a device that convert ac electric energy at convert ac electric energy at one voltage level at another one voltage level at another voltage level.voltage level.
Transformer are important to modern life
• Thomas A. Edison (1882)Power Distribution System : New York-USA ; 120 VdcProblems : Losses & Voltage Drop = inefficient
120 kVA 50 kVA 70 kVA
%58
Example :
120 V 70 kVA
Rs=0,05 ohm/10km1000 A
50 V
70V
1.
High Voltage
70 kV 70 kVA
Rs=0,05 ohm/10km1 A
0,05 V
70kV~
70 kVA 0,05 VA 70 kVA
Transformer
are important to modern power system
Low voltage High Voltage
Real Application on Power System
PM G TR MTR
380 V/20 kV 20 kV/380 V
Transformer
1. Power Frequency , 50/60 Hz
2. Radio frequency, > 30 kHz
1. Power Transformer
2. Instrument Transformer
2. Type and Construction Of Transformer
3. The Ideal Transformer
V P(t)
IP(t) IS(t)
V S(t)N P N S
+
-
+
-
S
P
N
Na a
N
N
tv
tv
S
P
S
P )(
)(Turn ratio a
The Ideal Transformer
V P(t)
IP(t) IS(t)
V S(t)N P N S
+
-
+
-
ati
ti
S
P 1
)(
)(Turn ratio a)(.)(. tINtiN SSPP
The Ideal Transformer
V P(t)
IP(t) IS(t)
V S(t)N P N S
+
-
+
-
aV
V
S
P aI
I
S
P 1
In term of phasor quantities
Power in ideal Transformer
PPPIN IVP cos SSSOUT IVP cos
SPcosSSOUT IVP
PSPS aIIandaVV /
INPP
OUT PaIa
VP cos
Power input
Power input
ideal
Turn ratio equation
Power in ideal Transformer
INPPOUT PIVP cos
INPPSSOUT QIVIVQ sinsin
INPPSSOUT SIVIVS
Active power
reactive power
Apparent power
Evaluasi
• Untuk memahami konsep trafo ideal berikan ke mahasiswa, contoh sederhana misalnya :– Cara mendapatkan tegangan sekunder y
volt jika tegangan primernya x volt.– Arus sekunder b ampere pada tegangan
y volt, cari arus primer a ampere pada tegangan X volt.
– Ambil nilai x dan y yang bedanya sangat besar
– Soal pada sistem 1 fasa dulu saja.
Impedance Transformer
L
LL I
VZ
Impedance =
ratio of the phasor voltage across it ti the phasor current
Z LV L
IL
Impedance Transformer
S
S
S
S
P
PL I
Va
aI
aV
I
VZ 2
/'
SP aVV
S
SL I
VZ
P
PL I
VZ '
aII SP /
LL ZaZ 2'
Z L
IP IS
V P V S
+
-
+
-
if
Theory of operation of real single-phase transformers
The basis transformer operation can be derived from Faraday’s law dt
deind
N
ii
1
Flux linkage N
dt
dNeind
VP(t)
IP(t) IS(t)
VS(t)N P N S
+
-
+
-
EMF equation of a transformer
dt
dNe
Faraday law of
electromagnetic induction
t cosmax
tNe sinmaxRMS Value
mm fN
NE
44,4
2
Transformer Losses
• Copper (I2R) losses• Eddy current losses• Hysteresis losses
• Leakage flux
The equivalent circuit of a
transformer
RPIP XP
Rc
Idealtransformer
+
-
PV
RSISXS
+
-
SVjXM NP NS
the model of a real transformer
The equivalent circuit of a
transformer
RP
IP
j XP
Rc
+
-
PVa2 RS
IS /a
j a2 XS
+
-
SaVjXM
Referred to primary
RP /a2
a IP j XP /a2
+
-
a/VP
RS
ISj XS
+
-
SVRC /a2 j XM /a
2
Referred to secondary
Phasor diagram corresponding – referred to primary
aV 2
aI 2R 2
I1R 1
j I1X1
ImI0 I1
I2 /a
IC
2
The equivalent circuit of a
transformer
ReqIP j Xeq
Rc
+
-
PV
IS /a
+
-
SaVjXM
Approximate transformer models
ImIh+e
Test on transformers
• Open-Circuit Test
transformer
Ip (t)wattmeter
+
-
Vp (t)
A
~ Vv(t)
• Result : VOC IOC POC
Open-Circuit Test Result
Conductance of the core-loss resistor C
C RG
1
MM X
B1
MCE jBGY CC
E Xj
RY
11
OC
OCE V
IY
Susceptance of the magnetizing inductor
Admittance
Magnitude admittance
Open-Circuit Test Result
OCOC
OC
IV
PPF
.cos
OCOC
OC
IV
P
.cos 1
OC
OCE V
IY
PFV
IY
OC
OCE
1cos
Power Factor
Power Factor angle
Admittance
Test on transformers
Short-Circuit Test
transformer
Ip (t)wattmeter
+
-
Vp (t)
A
~ V
IS (t)
v(t)
Result : VSC ,ISC ,POC
Short-Circuit Test Result
Series impedanceSC
SCSE I
VZ
SCSC
SC
IV
PPF
.cos
SCSC
SC
IV
P
.cos 1
Power Factor of the current
Lagging - Current angle (-),Impedance angle (+)
SC
SC
SC
SCSE I
V
I
VZ
00Therefore,
Short-Circuit Test Result
Admittance
eqeqSE jXRZ
)()( 22SPSPSE XaXjRaRZ
Series impedance
2.2
The equivalent circuit impedances of a 20 kVA, 8000 / 240 V, 60 Hz transformer are to be determined. The open circuit test were performed on the primary side of the transformer, and the following data were taken :
Open-circuit test (on primary)
Shots-circuit test (on primary)VOC = 8000 V
IOC = 0,214 A
POC = 400 W
VOC = 489 V
IOC = 2,5 A
POC = 240 W
pI a
Is
pV sVacR mXj
ehI mI
eqR eqXj
192j4.38
kj 4.38k159
+ +
- -
The per-unit system of measurement
quantityofvaluebase
quantityactualunitperQuantity
In single-phase system : basebasebasebasebase IVSorQP ,
base
basebase I
VZ
base
basebase V
IY
base
basebase S
VZ
2)(
Voltage Regulation & Efficiency
%100,
,, xV
VVVR
loadfullS
loadfullSloadnoS
Efficiency
%100xP
P
in
out %100xPP
P
lossout
out
Voltage Regulation
Autotransformer
ISE
ILV H
V L
N SE
N CIC
IHStep-down autotransformer
SE
C
SE
C
N
N
V
V SESECC ININ
CL VV SECH VVV
SEH II CSEL III
CSE
C
H
L
NN
N
V
V
C
CSE
H
L
N
NN
I
I
Power rating -autotransformer
SE
CSE
W
IO
N
NN
S
S
SIO =Input and Output apparent powers
SW = apparent power in the
transformer windings
For example, a 5000 kVA autotransformer connecting a 110 kV system to a 138 kV system would have an NC/NSE turn of ratio of 110 : 28. Such an autotransformer would actually have windings rated at :
kVAkVANN
NSS
SEC
SEIOW 10155000
11028
28
Three-phase transformer
N P1 N S1 N P2N S2 N P3 N S3
A three-phase transformer bank composed of independent transformer
N P1 N P2 N P3
N S1 N S2 N S3
A three-phase transformer wound on a single three-legged core
Three-phase transformer connections
• Wye-wye (Yy)• Wye-delta (Yd)• Delta-wye (Dy)• Delta-delta (Dd)
Wye-wye (Yy) Connection
aV
V
V
V
S
P
LS
LP
3
3
aV
V
S
P
Wye-delta (Yd) Connection
S
P
LS
LP
V
V
V
V
3
aV
V
LS
LP 3
Delta-wye (Dy) Connection
S
P
LS
LP
V
V
V
V
3
3
a
V
V
LS
LP
Delta-delta (Dd) Connection
aV
V
V
V
S
P
LS
LP
A 50 kVA 13.800 / 208 V, Dy distribution transformer has a resistance of 1 percent and reactance of 7 percent per unit.
(a) What is the transformer’s phase impedance referred to the high-voltage side?
(b) Calculate this transformer’s voltage regulation at full load and 0,8 PF lagging, using the calculated high-side impedance.
(c) Calculate this transformer’s voltage regulation under the same conditions, using the per-unit system.
Instrument transformers
• Potential transformer (PT)• Current transformers (CT)
V W
S
A
CT
PT